Featured Research

from universities, journals, and other organizations

Discovery suggests way to block fetal brain damage produced by oxygen deprivation

Date:

September 3, 2011

Source:

Scripps Research Institute

Summary:

Examining brain damage that occurs when fetuses in the womb are deprived of oxygen, researchers have discovered that damage does not occur randomly but is linked to the specific action of a naturally occurring fatty molecule called LPA, acting through a receptor that transfers information into young brain cells.

Share This

Examining brain damage that occurs when fetuses in the womb are deprived of oxygen, researchers at The Scripps Research Institute have discovered that damage does not occur randomly but is linked to the specific action of a naturally occurring fatty molecule called LPA, acting through a receptor that transfers information into young brain cells.

Related Articles

This observation made in mice suggests that LPA may also be linked to the damage caused by oxygen deprivation in human fetuses. If that proves to be the case, the research may help scientists and physicians better understand and find new ways to address the numerous developmental disorders that can arise when fetuses are deprived of oxygen in the womb -- including mental retardation, epilepsy, schizophrenia, autism, cerebral palsy and a range of other physical and mental problems.

"Fetal brain damage from oxygen deprivation involves specific changes that are, surprisingly, mediated by this lipid signal called LPA," said Scripps Research Professor Jerold Chun, MD, PhD, a member of the Dorris Neuroscience Center who led the research, which appeared in an advance, online issue of the journal Proceedings of the National Academy of Sciences (PNAS).

"Because this pathway can be targeted with drugs," he added, "the discovery suggests that creating new medicines that target LPA receptors may be a way of limiting or preventing serious developmental brain diseases."

Currently, there is no way to treat the neurological damage produced by oxygen deprivation.

How Lack of Oxygen Affects the Fetal Brain

A developing fetus might be temporarily deprived of oxygen -- a condition known as "hypoxia" -- for any number of reasons, including disruption of blood flow, exposure to smoke, carbon monoxide, or physical trauma.

Physicians have long known that hypoxia can lead to brain damage and increased risk of developmental disorders, and existing public health efforts are aimed at mitigating these risks. Awareness that carbon monoxide from cigarettes can cause hypoxia, for instance, is the major reason why women are warned not to smoke when they are pregnant.

Still, there is a need to find other ways to address the problem, since not every situation in which fetuses might be subjected to oxygen deprivation is preventable. The discovery by Chun, graduate student Keira Herr, and colleagues suggests that there may be a way to mitigate the damage caused by hypoxia directly, by drugs targeting the molecules in the brain that mediates this damage -- specifically, the receptor for the phospholipid molecule lysophosphatidic acid (LPA).

Phospholipids, molecules of fat with a charged head on one end, are universally found in biological organisms because they are an essential building block of cellular membranes, defining the boundaries of cells and keeping things inside a cell separated from that which is outside.

But lipids do more than just form barriers. LPA acts as a signal to affect the development of mammalian brains -- something that Chun and his colleagues first demonstrated several years ago. His laboratory identified the first cellular receptor to which LPA binds, and they discovered that LPA acts as a signal that influences neurogenesis, the formation of new neurons when fetal brains are developing in the womb, along with the architecture of the brain.

As the brain grows in developing fetuses, it forms specialized regions very quickly. Many of these regions must be up and running by the time a baby is born. Newborns need to be able to breathe, drink, digest, respond to stimuli, and function in countless other basic ways in order to survive.

Problems that arise as the early brain develops may lead to developmental disorders.

Findings that Provide a New Strategy to Block Damage

The prominent role LPA plays in fetal brain development is what led Chun and his colleagues to investigate whether it also played a role in developmental disorders, many of which are believed to be linked to brain disorganization that arises during early development as has been documented in the clinical literature following hypoxic insults.

The team studied the effect of hypoxia in the brains of developing mice and also on brains temporarily grown in Petri dishes. In particular, the researchers studied the changes that occur in young neurons of the cerebral cortex, the part of the brain believed to be involved in higher functions, like memory, cognition, reasoning, and the interpretation of sensory input.

Chun and his colleagues discovered that when hypoxia damages developing cerebral cortical neurons, it does so in very specific ways that require LPA signaling. Scientists had long assumed that the association between hypoxia and brain damage was a non-specific one in which individual neurons all over the brain were randomly killed as a result of being deprived of oxygen.

What Chun and his colleagues found, however, is that hypoxia causes the neurons to become overstimulated, mimicking effects produced by excessive LPA exposure. Genetically removing the receptors for LPA or blocking them through drugs stopped these effects.

Knowing that hypoxia causes brain damage through this LPA signaling pathway provides a strategy to target and block that damage. Blocking LPA signaling may be a new way to prevent damaging changes to the brain and attenuate or prevent diseases linked to hypoxia, a concept that awaits further testing in humans.

Scripps Research Institute. (2011, September 3). Discovery suggests way to block fetal brain damage produced by oxygen deprivation. ScienceDaily. Retrieved March 31, 2015 from www.sciencedaily.com/releases/2011/09/110901142625.htm

More From ScienceDaily

More Mind & Brain News

Featured Research

Mar. 31, 2015 — Memory and as well as connections between brain cells were restored in mice with a model of Alzheimer's given an experimental cancer drug, researchers report. "With this treatment, cells under ... full story

Mar. 31, 2015 — A criminologist finds that solitary confinement does not deter inmates from committing further violence in prison. The prisoners in the study who received solitary confinement were no more -- or less ... full story

Mar. 31, 2015 — Alcoholism takes a toll on every aspect of a person's life, including skin problems. Now, a new research report helps explain why this happens and what might be done to address it. "The clinical ... full story

Mar. 31, 2015 — Human language likely developed quite rapidly into a sophisticated system, a linguist contends. Instead of mumbles and grunts, people deployed syntax and structures resembling the ones we use today, ... full story

Mar. 31, 2015 — Coronary heart disease and stroke, two of the leading causes of death in the United States, are diseases associated with heightened platelet reactivity. A new study in humans suggests an underlying ... full story

Mar. 31, 2015 — A new study had researchers seeking answers to why the therapeutic benefit afforded by SSRIs was so limited in children and teenagers. If researchers can uncover the biological mechanisms preventing ... full story

Mar. 31, 2015 — New research reveals high-quality early education is especially advantageous for children when they start younger and continue longer. Not only does more high-quality early education significantly ... full story

Mar. 31, 2015 — During prenatal development, the brains of most animals, including humans, develop specifically male or female characteristics. But scientists have known little about the details of how this ... full story

Mar. 31, 2015 — A history of depression may put women at risk for developing diabetes during pregnancy, according to research. This study also pointed to how common depression is during pregnancy and the need for ... full story

Featured Videos

AAA: Distracted Driving a Serious Teen Problem

AP (Mar. 25, 2015) — While distracted driving is not a new problem for teens, new research from the AAA Foundation for Traffic Safety says it&apos;s much more serious than previously thought. (March 25)
Video provided by AP

Many Don't Know They Have Alzheimer's, But Their Doctors Do

Newsy (Mar. 24, 2015) — According to a new study by the Alzheimer&apos;s Association, more than half of those who have the degenerative brain disease aren&apos;t told by their doctors.
Video provided by Newsy

A Quick 45-Minute Nap Can Improve Your Memory

Newsy (Mar. 23, 2015) — Researchers found those who napped for 45 minutes to an hour before being tested on information recalled it five times better than those who didn&apos;t.
Video provided by Newsy

Related Stories

Nov. 27, 2014 — A mechanism linked to the brain damage often suffered by stroke victims has been discovered by scientists, who are now searching for drugs to block it. Strokes happen when the blood supply to part of ... full story

Mar. 13, 2014 — A new study in animals shows that using a compound to block the body’s immune response greatly reduces disability after a stroke. The study also showed that particular immune cells -- CD4+ T-cells ... full story

Feb. 24, 2013 — The origin of an innate ability the brain has to protect itself from damage that occurs in stroke has been explained for the first time. Researchers hope that harnessing this inbuilt biological ... full story

Aug. 24, 2010 — When human umbilical cord blood cells were used to treat cultured rat brain cells deprived of oxygen, the cells appeared to protect astrocytes from cell death after stroke-like damage. Researchers ... full story

ScienceDaily features breaking news and videos about the latest discoveries in health, technology, the environment, and more -- from major news services and leading universities, scientific journals, and research organizations.